Reduced Order Electrochemical-Thermal Modeling of Cylindrical Cells Containing Graphite-Silicon Anodes Considering Thermal Gradients and Hysteresis

Du, Xiaoniu; Park, Junbeom; Choe, Song-Yul; Garrick, Taylor R.; Dix, Sean T.; Zhang, Han

doi:10.1149/1945-7111/ad4ac6

J. Electrochem. Soc.

2024

DOI: 10.1149/1945-7111/ad4ac6

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Reduced Order Electrochemical-Thermal Modeling of Cylindrical Cells Containing Graphite-Silicon Anodes Considering Thermal Gradients and Hysteresis

Xiaoniu Du,

Junbeom Park,

Song-Yul Choe

et al.

Abstract: Electrochemical thermal modeling of cylindrical cells presents unique challenges compared to other cell formats due to the effect of internal temperature gradients, which typically requires time-consuming simulations due to the number of mesh elements solved numerically. Adding to the difficulty, the emergence of silicon anodes induces voltage hysteresis that affects the cell behavior. In this paper, a reduced-order electrochemical-thermal model is developed for a 21700 cell, which is highlighted by three micr… Show more

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Cited by 4 publications

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Assessing degradation modes in cylindrical lithium-ion batteries: A non-invasive method using the entropic heat flow or surface temperature

Kunz,

Kirst,

Durdel

et al. 2025

Journal of Power Sources

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Assessing degradation modes in cylindrical lithium-ion batteries: A non-invasive method using the entropic heat flow or surface temperature

Kunz,

Kirst,

Durdel

et al. 2025

Journal of Power Sources

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Quantifying the Impact of Microstructure Variation on Charging Capability in Lithium-Ion Batteries

Teel,

Garrick,

Sepe

et al. 2024

J. Electrochem. Soc.

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Through the use of electrochemical simulations, variation in the local onset of lithium plating can be predicted and used to set charging guidelines to reduce the risk of lithium plating. The pseudo-two-dimensional (P2D) model is typically used for capturing this behavior; however, it only provides a global lithium plating onset estimate and does not consider the local variation. With material properties translated to an average continuum value, the P2D model can simulate rapid charge and capture global onset of lithium plating. However, this model lacks the ability to resolve localized behaviors across individual components due to local non-uniformities. Our three-dimensional microstructure-based (3DMS) modeling method that we employ to simulate rapid charge and capture local performance across the electrochemical components while agreeing with P2D model. Using the 3DMS model, we predict the onset of local lithium plating to design more conservative charging conditions to delay the onset of lithium plating and improve the performance of these electrochemical systems. In this work, several similar microstructures are evaluated for the lithium plating onset time during fast charge operation. A small normal distribution for particle sizes are explored to drive variation in performance and are compared to a uniform particle size structure.

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Addressing Strain and Porosity Changes of Battery Electrodes Due to Reversible Expansion through DEM Simulations

Teel,

Garrick,

Srinivasan

et al. 2024

J. Electrochem. Soc.

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In this work, discrete element method (DEM) simulations were used to probe changes in electrode porosity, electrode strain, and the resultant pressure changes for composite electrodes comprised of active material and binder particles. Through the results acquired by these simulations, three cases that are representative of two limiting cases for electrode operation, and one case for realistic electrode face pressure during operation were captured and the implications on design and performance are discussed. Predicting changes in the porosity is a unique insight that is difficult if not impossible to capture experimentally but is important for predicting changes in electrochemical performance during cycling, and should be addressed early on in the design phase for automotive and grid storage battery design and performance.

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Reduced Order Electrochemical-Thermal Modeling of Cylindrical Cells Containing Graphite-Silicon Anodes Considering Thermal Gradients and Hysteresis

Cited by 4 publications

References 65 publications

Assessing degradation modes in cylindrical lithium-ion batteries: A non-invasive method using the entropic heat flow or surface temperature

Assessing degradation modes in cylindrical lithium-ion batteries: A non-invasive method using the entropic heat flow or surface temperature

Quantifying the Impact of Microstructure Variation on Charging Capability in Lithium-Ion Batteries

Addressing Strain and Porosity Changes of Battery Electrodes Due to Reversible Expansion through DEM Simulations

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